A. Koniger et al., INVESTIGATION OF PLASMA IMMERSION ION-IMPLANTED NIOBIUM OXIDE AND TITANIUM NITRIDE FILMS BY NANOHARDNESS MEASUREMENT, Nuclear instruments & methods in physics research. Section B, Beam interactions with materials and atoms, 120(1-4), 1996, pp. 282-285
Plasma immersion ion implantation has to date mainly been used for sur
face and near-surface treatment of bulk material. On the other hand, i
t also allows for implantation into thin films. When rare gas ions are
used this treatment may alter the microstructure of the films. Applic
ation of reactive ions additionally changes the composition and may le
ad to formation of compound phases such as oxides and nitrides. Thin f
ilms of niobium and titanium were deposited onto steel and silicon by
electron beam evaporation. The films were then subjected to plasma imm
ersion implantation. For niobium, an RF excited oxygen plasma was used
. Titanium was treated with a nitrogen ECR microwave plasma. The resul
ting oxide and nitride films were analyzed by depth-sensing nanohardne
ss measurements. The results were correlated with analytical findings
from Rutherford backscattering and X-ray diffraction measurements. It
turns out that nitrogen ion implantation into titanium yields an incre
ase in hardness with increasing process time. By contrast, oxygen inco
rporation into niobium leads to a reduction in hardness which could be
correlated with the oxygen content. With increasing amount of oxygen
entering the film from the surface, the hardness decreases, starting f
rom the surface and following the oxygen amount in depth. Observed har
dness profile and stoichiometry profile investigated by RES exhibit th
e same multilayered structure.